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Animesh A Bose

from Durham, NC
Age ~72
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Also known as:
Anjana Bose, Aminesh Bose, Arimesh Bose
Related to:
Sanjukta BoseDeena Bose
Connected to:
Amritanshu Bose, 37Anand Bose, 46Anindita Bose, 47Anindya Bose, 68Ann Bose, 75Anupam Bose, 51Asha Bose, 39Ashoke Bose, 67Bethel C Bose, 88Bonnie Bose, 73

Animesh Bose Phones & Addresses

  • Durham, NC
  • Baltimore, MD
  • 4413 Ledgeview Rd, Fort Worth, TX 76109 (817) 922-0253 (817) 922-9193
  • 6401 Elm Crest Ct, Fort Worth, TX 76132 (817) 361-7988 (817) 294-0135
  • Haltom City, TX
  • 4 Great Pines Ave, Burlington, MA 01803 (972) 313-2560
  • Irving, TX
  • Carmel, IN
  • Dallas, TX
  • Madison, WI
  • 6401 Elm Crest Ct, Fort Worth, TX 76132 (817) 903-7791

Work

Position: Service Occupations

Education

Degree: High school graduate or higher

Emails

a***[email protected]

Resumes

Resumes

Animesh Bose Photo 1

Vice President Of Research And Development

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Location:
6401 Elm Crest Ct, Fort Worth, TX 76132
Industry:
Research
Work:
Materials Processing 1999 - 2016
President
Desktop Metal 1999 - 2016
Vice President of Research and Development
Advanced Metalworking Practices, Llc 2008 - 2009
General Manager
Powdermet, Inc. 1995 - 1997
Executive Vice President
Material Innovations Corp 1995 - 1995
Founder
Education:
Indian Institute of Technology, Kharagpur 1982 - 1982
Doctorates, Doctor of Philosophy Indian Institute of Technology, Kharagpur 1977 - 1977
Bachelors, Metallurgical Engineering Haldia Institute of Technology 103
Bachelors, Bachelor of Technology Indiana University - Kelley School of Business
Bachelors, Bachelor of Science
Skills:
Manufacturing
Materials
Manufacturing Operations Management
Continuous Improvement
Materials Science
Product Development
Metallurgy
R&D
Engineering
Failure Analysis
Metals
Injection Molding
Manufacturing Engineering
Coatings
Design of Experiments
Machining
Project Management
Composites
Iso
Nanotechnology
Characterization
Steel
Polymers
Extrusion
Metal Fabrication
Aluminum
Stainless Steel
Powder Metallurgy
Languages:
English
Bengali
Hindi
Animesh Bose Photo 2

Animesh Bose

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Business Records

Name / Title
Company / Classification
Phones & Addresses
Animesh Bose
Director
3 Innovations, Inc
Engineering Services
4413 Ledgeview Rd, Fort Worth, TX 76109
Animesh Bose
Director
SHAPING CONCEPTS LLC
1439 Santa Anita Blvd, Irving, TX 75060
1105 Arwine Ct, Euless, TX 76040
4413 Ledgeview Rd, Fort Worth, TX 76109
Animesh Bose
Principal
Materials Processing Inc
Management Consulting Services
6401 Elm Crst Ct, Fort Worth, TX 76132
Animesh Bose
Director
SRI KRISHNA LLC
4221 Kirkland Ct, Fort Worth, TX 76109
6401 Elm Crst Ct, Fort Worth, TX 76132

Publications

Us Patents

Abrasive Particles With Metallurgically Bonded Metal Coatings

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US Patent:
6540800, Apr 1, 2003
Filed:
Dec 7, 2000
Appl. No.:
09/732834
Inventors:
Andrew J. Sherman - Granada Hills CA
Animesh Bose - Fort Worth TX
Assignee:
Powdermet, Inc. - Sun Valley CA
International Classification:
C09K 314
US Classification:
51309, 51295, 51293, 51307
Abstract:
An abrasive composite particle comprising a cubic abrasive core particle encapsulated within a deposit of hexagonal metallurgical bond forming material comprising at least about 50 volume percent rhenium, ruthenium, osmium or mixtures thereof. The metallurgical bonds serve to retain the core particle in a matrix/binder very strongly. Metallurgical bonds are formed by the encapsulating material taking into solution, at the interface with the cubic abrasive core particle, some element or compound from the abrasive particle such as, for example, carbon or cubic boron nitride, from the core particle. Chemical bonds are not formed between the abrasive particle and the deposit. Suitable abrasive core particles include diamond, cubic carbides, cubic borides, cubic nitrides, cubic oxides, and the like. Conventional fabrication procedures such as chemical vapor deposition are employed to form the metallurgical bond forming deposit on the core particle. The composite abrasive particles are useful in forming articles according to conventional powdered metal processing operations.

Method Of Producing Fine Coated Tungsten Carbide Particles

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US Patent:
6641918, Nov 4, 2003
Filed:
May 30, 2000
Appl. No.:
09/583061
Inventors:
Andrew J. Sherman - Granada Hills CA
Animesh Bose - Fort Worth TX
Assignee:
Powdermet, Inc. - Sun Valley CA
International Classification:
B32B 516
US Classification:
428403, 428404, 428407, 427213, 427214, 427215, 427216, 427217, 427251, 427252
Abstract:
Geldhart class C tungsten carbide particles are provided with a discontinuous coating of grain growth inhibitor. Further, the fine tungsten carbide coatings are preferably provided with a continuous coating of another discreet phase material, such as, for example, a continuous coating of cobalt. Compacts produced using such materials are particularly useful as WCâCo hardmetals wherein the compacts are extremely fine grained.

Joining Of Tungsten Alloys

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US Patent:
8100318, Jan 24, 2012
Filed:
Feb 11, 2010
Appl. No.:
12/703815
Inventors:
Animesh Bose - Fort Worth TX, US
Morris F. Dilmore - Baker FL, US
Alan J. Armstrong - Fort Walton Beach FL, US
Assignee:
The United States of America as represented by the Secretary of the Air Force - Washington DC
International Classification:
B23K 20/00
US Classification:
228194, 228193
Abstract:
A process of making useful shapes by joining of tungsten alloys. Joining of tungsten heavy alloys which are alloys typically made from W—Ni—Fe is used. These alloys are typically manufactured by liquid phase sintering. This leads to difficulty in producing large length to diameter ratio parts that have some significant weight (such as penetrators). A “brick and mortar” approach is employed wherein smaller segments of this alloy (low length to diameter ratio) are joined to together to produce a larger part with higher length to diameter ratio.

Processing Of Rifled Gun Barrels From Advanced Materials

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US Patent:
20080120889, May 29, 2008
Filed:
Jul 3, 2006
Appl. No.:
11/480639
Inventors:
Animesh Bose - Fort Worth TX, US
Robert J. Dowding - Abingdon MD, US
Jeffrey J. Swab - Fallston MD, US
International Classification:
F41A 21/04
B22F 3/02
B22F 5/12
US Classification:
42 7602, 419 66, 419 65, 419 5
Abstract:
Gun barrels made from advanced materials have the potential to provide a significant increase in barrel life as well as a reduction in weight (for advanced ceramic materials) for small caliber systems. The potential use of advanced materials as gun barrels is severely limited due to the difficulty in introducing the rifling pattern on the inner diameter. Most projectiles coming out of the guns are spin stabilized (for aerodynamic flight stability). This spin is imparted by a rifling pattern (lands and grooves) in the inner surface of the gun barrel. The processing of gun barrels made from advanced materials with internal rifling pattern poses a tremendous processing challenge to the materials community. The rifling lands and grooves and desired twist rate coupled with the difficulty of machining some of the advanced materials (ceramics, cermets, hardmetals, etc.) makes the economic manufacturing of such gun barrels extremely difficult. Currently, this form of rifling is achieved by machining in case of metallic gun barrels.The limitation in producing the rifled pattern lies with the conventional processing of complex shaped advanced materials such as ceramics, cermets, or hardmetals. Shaping of these typically requires careful diamond grinding. This grinding process is not only very expensive but it also introduces flaws in case of the brittle ceramics (microcracks). These flaws are detrimental to the performance of these advanced materials as rifled gun barrels. Thus, there is an opportunity and challenge to the materials community to come up with a processing solution that will allow advanced materials such as silicon nitride (SiN), SiAlON, hardmetals, etc. to be used as gun barrels that have the rifled pattern in the inner diameter.Herein are provided methods and compositions useful to form the rifled gun barrel tubes from advanced materials using little or no machining of the internal rifled geometry.

Method And System For Software Defined Metallurgy

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US Patent:
20220326668, Oct 13, 2022
Filed:
Jan 10, 2022
Appl. No.:
17/572521
Inventors:
- Burlington MA, US
Brian D. Kernan - Andover MA, US
Animesh Bose - Burlington MA, US
Mark Sowerbutts - Townsend MA, US
Assignee:
Desktop Metal, Inc. - Burlington MA
International Classification:
G05B 15/02
B22F 3/10
G06F 3/04847
B33Y 30/00
B33Y 50/02
G06F 3/0482
B33Y 10/00
B22F 3/00
F27D 19/00
F27D 21/00
B33Y 40/00
B22F 3/24
B22F 10/10
Abstract:
A system for generating a user-adjustable furnace profile, comprises a user interface configured to receive one or more materials properties from a user, a processor, and a memory with computer code instructions stored thereon. The memory is operatively coupled to the processor such that, when executed by the processor, the computer code instructions cause the system to implement communicating with a furnace to ascertain one or more thermal processes associated with the furnace, identifying one or more object characteristics associated with an object to be processed by furnace, and determining a thermal processing parameter profile of at least one thermal processing parameter corresponding to each of the thermal processes, based on (i) the one or more part characteristics and (ii) the one or more materials properties, the thermal processing parameter profile characterizing a cycle of the one or more thermal processes.

Material Systems For Additive Manufacturing

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US Patent:
20210283688, Sep 16, 2021
Filed:
Dec 14, 2017
Appl. No.:
16/328632
Inventors:
- Burlington MA, US
Animesh Bose - Burlington MA, US
Michael Andrew Gibson - Boston MA, US
Richard Remo Fontana - Cape Elizabeth ME, US
Jonah Samuel Myerberg - Lexington MA, US
Assignee:
Desktop Metal, Inc. - Burlington MA
International Classification:
B22F 10/18
B33Y 10/00
B33Y 40/20
B22F 3/24
B28B 1/00
Abstract:
Techniques and compositions are disclosed for three-dimensional printing with powder/binder systems including, but not limited to, metal injection molding powder materials, highly-filled polymer composites, and any other materials suitable for handling with various additive manufacturing techniques, and further suitable for subsequent debinding and thermal processing into a final object.

Methods And Compositions For The Preparation Of Powders For Binder-Based Three-Dimensional Additive Metal Manufacturing

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US Patent:
20210260652, Aug 26, 2021
Filed:
Jun 20, 2019
Appl. No.:
17/254805
Inventors:
- Burlington MA, US
Animesh Bose - Burlington MA, US
Assignee:
DESKTOP METAL, INC. - Burlington MA
International Classification:
B22F 1/02
B22F 10/14
B22F 10/62
B22F 1/00
B33Y 10/00
B33Y 30/00
B33Y 70/10
B33Y 80/00
Abstract:
Devices, systems, and methods are directed to coated powder for three dimensional additive manufacturing. The powder may include a first material coated with a second material, with the coating advantageously resisting segregation of the first material and the second material during handling processes associated with fabrication. The reduced segregation of the first material and the second material may facilitate forming finished three-dimensional parts with improved homogeneity of microstructures and, thus, improved physicochemical properties. More generally, the reduced segregation of the first material and the second material achievable through coating the first material with the second material may facilitate binder jet fabrication using a wider array of combinations of first material and second material as compared to binder jet fabrication using mixtures of constituent powders of the first material and the second material.

Thermal Debinding Techniques For Additive Manufacturing And Related Systems And Methods

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US Patent:
20210260654, Aug 26, 2021
Filed:
Jan 26, 2021
Appl. No.:
17/158673
Inventors:
- Burlington MA, US
Nihan Tuncer - Cambridge MA, US
Animesh Bose - Burlington MA, US
Christopher Craven - Bedford MA, US
Alexander C. Barbati - Melrose MA, US
Ricardo Fulop - Lexington MA, US
Karl-Heinz Schofalvi - Hudson OH, US
Assignee:
Desktop Metal, Inc. - Burlington MA
International Classification:
B22F 3/10
B22F 10/14
B22F 10/64
B33Y 10/00
B33Y 50/00
B33Y 40/20
Abstract:
Techniques for debinding additively fabricated parts are described that do not require solvent debinding or catalytic debinding, and that may be performed using only thermal debinding in a furnace. As a result, in at least some cases debinding and sintering may take place sequentially within a single furnace. In some embodiments, the techniques may utilize particular materials as binders that allow for a thermal debinding process that does not negatively affect the parts.

Isbn (Books And Publications)

Reviews in Particulate Materials 1994

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Author

Animesh Bose

ISBN #

0614049199

Advances in Particulate Materials

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Author

Animesh Bose

ISBN #

0750691565

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Animesh A Bose from Durham, NC, age ~72 Get Report